Horizontal stripe liquid crystal display device

ABSTRACT

A liquid crystal display device for improving picture quality includes a common electrode formed on a first substrate, gate lines and data lines formed on a second substrate bonded to the first substrate by a sealing member with liquid crystals disposed therebetween, thin film transistors connected to the gate lines and to the data lines, pixel electrodes formed in subpixel regions, each pixel electrode having a long side in a direction of the gate lines and having a short side in a direction of the data lines fanout lines for supplying a driving signals from the driving chips to the data lines, first conductive spacers formed between the fanout lines connected to different driving chips, for supplying a common voltage to the common electrode, and second conductive spacers formed between the fanout lines connected to the same driving chip, for supplying the common voltage to the common electrode.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No.11/527,115 filed on Sep. 26, 2006, the disclosure of which is hereinincorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a liquid crystal display device, andmore particularly, to a liquid crystal display device having horizontalstripes of same-color subpixels using the same gate lines, and capableof improving picture quality by preventing crosstalk.

2. Description of the Related Art

A liquid crystal display (“LCD”) device displays an image through apixel matrix using electro-optical properties of liquid crystals. Eachpixel (three colored subpixels) of the LCD device represents a desiredcolor by a combination of red, green and blue subpixels controllinglight transmittance by varying the arrangement of the liquid crystals inresponse to a data signal. Each subpixel contains liquid crystals thatare controlled by a voltage difference (electric field) applied to apixel electrode as a data signal supplied through a thin film transistor(“TFT”) (a switching element) and a common voltage supplied to a commonelectrode. The TFT is turned ON by a gate-ON voltage supplied via a gateline, thus passing the data signal supplied via a data line to the pixelelectrode, and is turned OFF by a gate-OFF voltage supplied via the gateline. The gate-OFF voltage applied to the gate line should be keptstable so that the data signal charged to the pixel electrode can becontrolled.

However, a ripple phenomenon occurs such that the common voltage swingsalong the data signal supplied to the data line(s) due to a coupling bya parasitic capacitance between the data line(s) and the commonelectrode overlapping each other with the liquid crystals disposedtherebetween, resulting in crosstalk. Especially when a specific imagedata pattern having a severely biased polarity is displayed on a screen,the crosstalk becomes more severe and the ripple component of the commonvoltage is increased.

SUMMARY OF THE INVENTION

The R, G and B subpixels of each pixel are arranged in a verticalsequence and are driven by the same data line, and subpixels of the samecolor (of different pixels) are horizontally arranged in a horizontalstripe and are driven by the same gate line. The LCD device reduces thenumber of data lines to one third compared to a conventional “verticalstripe” LCD device.

An aspect of the present invention provides an LCD device capable ofimproving picture quality by preventing crosstalk.

An exemplary embodiment of the invention provides a liquid crystaldisplay (LCD) device. The LCD device includes a common electrode formedon a first substrate, gate lines and data lines formed on a secondsubstrate bonded to the first substrate by a sealing member with liquidcrystals disposed therebetween and the data lines and gate linesintersect each other, thin film transistors connected to the gate linesand to the data lines, pixel electrodes formed in subpixel regions eachhaving a long side in the direction of the gate lines and having a shortside in the direction of the data lines and connected to the thin filmtransistors, driving chips mounted on circuit films, for driving thedata lines, fanouts (fanout lines) for supplying a driving signal fromthe driving chips to the data lines, first conductive spacers (firstconductive spacers, extending and conducting between the first andsecond substrates) formed between the fanout lines connected todifferent driving chips, for supplying a common voltage to the commonelectrode, and second conductive spacers (first conductive spacers,extending and conducting between the first and second substrates) formedbetween the fanout lines connected to the same driving chip, forsupplying the common voltage to the common electrode.

The LCD device further includes a common voltage supply line formedperpendicular to the fanout lines, for connecting the first and secondconductive spacers to each other.

The common voltage supply line is formed in plural numbers so that itcan be separated according to the fanout lines connected to the samedriving chip.

Different common voltages are supplied to different (separate) commonelectrode corresponding to regions corresponding to the fanout lines.

The second conductive spacers are adjacent to the fanout line positionedat the center among the fanout lines connected to the same driving chip.

The LCD device further includes a plurality of storage lines formedalong the short side via the subpixel region.

The LCD device further includes storage supply lines formed according tothe fanout lines connected to the same driving chip and connected incommon to the storage lines.

The storage supply lines supply different storage voltages according tostorage lines positioned in regions corresponding to the fanout linesconnected to the same driving chip.

The storage supply lines perpendicular to the fanout lines are formed tooverlap the sealing member.

The sealing member includes a soft spacer.

The LCD device further includes a passivation layer formed of an organicinsulating layer to cover the fanout lines with a thickness capable ofbuffering pressure of the sealing member.

Another exemplary embodiment of the invention provides an a liquidcrystal display (LCD) device according to the present invention, the LCDdevice includes a common electrode formed on a first substrate, a gateline and a data line formed on a second substrate bonded to the firstsubstrate by a sealing member with liquid crystals disposed therebetweenand the data lines intersect each other, a thin film transistorconnected to the gate line and to the data line, a pixel electrodeformed in a subpixel region having a long side in a direction of thegate line and having a short side in a direction of the data line andconnected to the thin film transistor, a plurality of storage linesformed along the short side via the subpixel region, and a storagesupply line that is connected in common to the plurality of storagelines and overlaps at least a part of the sealing member.

The LCD device further includes a conductive spacer formed on the secondsubstrate, for supplying a common voltage to the common electrode, and afeedback dot adjacent to the conductive spacer, for feeding back thecommon voltage.

A compensation signal having a phase opposite to the common voltage fedback through the feedback dot is supplied to the storage line.

The storage supply line is formed to have a width ranging from 4 mm to 6mm.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other features of the present invention will become moreapparent to persons skilled in the art from the following detaileddescription when taken in conjunction with the accompanying drawings, inwhich:

FIG. 1 is a schematic view of an LCD device according to a firstexemplary embodiment of the present invention;

FIG. 2 is a plan view illustrating two subpixels in a TFT substrate ofthe LCD device of FIG. 1;

FIG. 3 is a plan view illustrating pads connected to a circuit film andto first and second conductive spacers in the LCD device in FIG. 1;

FIGS. 4A and 4B are alternative cross-sectional views taken alongsection line I-I′ in FIG. 3 illustrating alternative embodiments of anupper pad electrode 146 connecting the first and second conductivespacers;

FIG. 5 is a schematic view of an LCD device according to a secondexemplary embodiment of the present invention;

FIG. 6 is a schematic view of an LCD device according to a thirdexemplary embodiment of the present invention;

FIG. 7 is a schematic view of an LCD device according to a fourthexemplary embodiment of the present invention;

FIG. 8 is an enlarged plan view illustrating a portion ‘A’ in FIG. 7;and

FIG. 9 is a cross-sectional view illustrating the LCD device of FIG. 7taken along section line II-II′ in FIG. 8.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 is a schematic view of a liquid crystal display (LCD) deviceaccording to a first exemplary embodiment of the present invention.

Referring to FIG. 1, the LCD device includes an LCD panel 130 in whichfirst and second gate drivers 102 and 112 for driving gate lines GL1 toGLn of the image display unit (pixel array) 108 are formed, circuitfilms (e.g., tape carrier packages or chip-on-films) 170 have datadriving chips 104 mounted thereon for driving data lines DL of the imagedisplay unit (pixel array) 108 and are connected between a printedcircuit board (PCB) 154 and the LCD panel 130. A timing controller 106is mounted on the PCB 154.

The first and second gate drivers 102 and 112 are located at oppositesides of the image display unit 108 and respectively drive the odd andeven gate lines among GL1 to GLn. For example, the first gate driver 102drives odd gate lines GL1, GL3, . . . , Gn−1 and the second gate driver112 drives even gate lines GL2, GL4, . . . , GLn. The first and secondgate drivers 102 and 112 are comprised of shift registers (e.g.,including a plurality of thin film transistors, TFTs) and are mounted ina non-display region i.e., outside of the image display unit (pixelarray) 108. Therefore, the first and second gate drivers 102 and 112 maybe formed together with pixel switching TFTs and a plurality of signallines DL, GL and SL of the image display unit (pixel array) 108. Thefirst and second gate drivers 102 and 112 sequentially drive the gatelines GL1 to GLn of the image display unit 108 by using gate controlsignals received from the timing controller 106 and gate-ON and gate-OFFvoltages received from a power source 164.

A plurality of data driving chips 104 for separately driving sets of thedata lines DL of the image display unit 108 are respectively mounted onthe plurality of circuit films 170. The circuit films 170 are attachedto the LCD panel 130 and to the PCB 154 through anisotropic conductivefilms. Anisotropic Conductive Film (ACF) is a material used forinterconnecting LCD drive-use semiconductor chip-mounted tape carrierpackage (TCP) circuits and the electrodes of LCD panels, as well as forconnecting TCP circuits to printed wiring board circuits. Tape carrierpackages or chip-on-films are used as the circuit films 170 on which thedata driving chips 104 are mounted. The data driving chips 104 may bedirectly mounted on a TFT substrate 110 of the LCD panel 130 by using achip-on-glass technique without using the circuit films 170. The datadriving chips 104 convert digital data from the timing controller 106into an analog data signals by using a gamma voltage from a gammavoltage generator (or gray voltage generator) (not shown) and supply theanalog data signals to the data lines DL in synchronization with eachhorizontal period during which the gate lines GL1 to GLn of the imagedisplay unit 108 are driven.

The timing controller 106 mounted on the PCB 154 controls the datadriving chips 104 and the first and second gate drivers 102 and 112. Adata signal and a plurality of data control signals from the timingcontroller 106 are supplied to the data driving chips 104 via the PCB154 and via the circuit films 170, and a plurality of gate controlsignals from the timing controller 106 are supplied to the first andsecond gate drivers 102 and 112 via the PCB 154, via the circuit films170, and via the TFT substrate 110 of the LCD panel 130.

The image display unit (pixel array) 108 of the LCD panel 130 displaysimages by activating a plurality of pixels arrayed in a matrix format,each pixel consisting of red (R), green (G), and blue (B) subpixels. Theimage display unit (pixel array) 108 is formed by bonding the TFTsubstrate 110, on which TFTs are formed (to switchably control each ofthe R, G and B subpixels), to a color filter substrate 113 where colorfilters are formed (for each of the R, G and B subpixels), with liquidcrystal molecules disposed therebetween. The R, G and B subpixels arearranged in a vertical sequence and subpixels of the same color arehorizontally arranged in a horizontal stripe. By the verticalarrangement of the R, G and B subpixels on the image display unit (pixelarray) 108, the LCD device reduces the number of data lines DL to onethird of the data lines of a comparable LCD device in which the R, G andB subpixels are alternated in a horizontal direction. As a result, thenumber of data driving chips 104 for driving the data lines DL isreduced by two thirds. Although the number of the gate drivers 102 and112 increases (because the number of gate lines GL1 to GLn increases) asthe number of data lines DL decreases (due to the vertical arrangementof the R, G and B subpixels), since the circuit configuration of thegate drivers 102 and 112 is simpler than that of the data driving chips104, manufacturing cost can be reduced. Since the gate drivers 102 and112 are mounted within the TFT substrate 110 using an amorphous siliconthin film, the manufacturing cost of the LCD device having fewer datalines, and more gate lines according the embodiments of the presentinvention can be greatly reduced compared to that of the conventionalLCD device.

FIG. 2 is a plan view illustrating two subpixels in a TFT substrate ofthe LCD device of FIG. 1.

Each subpixel in the image display unit (pixel array) 108 on the TFTsubstrate 110 includes, as shown in FIG. 2, a (horizontally elongatedrectangular) pixel electrode 132 formed in a subpixel region defined byan intersection of a gate line GL and of a data line DL, and a thin filmtransistor (TFT) 100 connected between the gate line GL, the data lineDL and the pixel electrode 132.

The gate line GL and the data line DL are formed perpendicular to eachother on an insulating substrate with a gate insulating layer disposedtherebetween. Each subpixel region is defined by an intersection of thegate line GL and the data line DL. A storage line SL is formed on theinsulating substrate in parallel with the data line DL to pass throughthe center of each subpixel (e.g., along a short side of the subpixel).

The TFT 100 includes a gate electrode 136 connected to the gate line GL,a source electrode 138 connected to the data line DL, a drain electrode134 connected to the pixel electrode 132, and a semiconductor layerconnected to the source electrode 138 and to the drain electrode 134.The semiconductor layer includes an active layer for forming a channelbetween the source electrode 138 and the drain electrode 134, and anohmic contact layer for an ohmic contact of the active layer, the sourceelectrode 138 and the drain electrode 134. The channel in thesemiconductor layer is formed over a gate electrode 136. Thesemiconductor layer is formed under the data line DL and the storageline SL. The TFTs 100 formed in two subpixel regions that are verticallyadjacent to each other (as shown in FIG. 2) are respectively connectedto right and left data lines which have opposite polarity. Theconnecting directions of the TFTs connected to the data lines DLalternate along a vertical direction. For example, the TFTs 100 of oddhorizontal lines connected to the odd gate lines GLi are connected tothe pixel electrodes 132 on the left of the data line DLj+1. In otherwords, the subpixels in odd horizontal lines have TFTs 100 connected tothe data lines DLj+1 on the right side of the subpixel. The TFTs 100 ofeven horizontal lines connected to the even gate lines GLi+1 areconnected to the pixel electrodes 132 on the right of the data line DLj.In other words, the subpixels in even horizontal lines have TFTs 100connected to the data lines DLj on the left side of the subpixel.Accordingly, the polarity of the data signal supplied to each of thedata lines DLj to DLj+1 is opposite to that of the data signal suppliedto its adjacent data lines DL. Even if the polarity of the data signalis inverted only on a frame basis, the pixel electrode 132 is alwayscharged by the data signal having a polarity opposite to the polarity ofhorizontally and vertically adjacent pixel electrodes 132 (e.g., isdriven by dot inversion).

The pixel electrode 132 is connected to the drain electrode 134 of theTFT 100 through a contact hole 128 (penetrating a passivation layer). Anelectric field is formed between the pixel electrode 132 and a commonelectrode at the color filter substrate 113, to arrange liquid crystalmolecules therebetween. The pixel electrode 132 overlaps the storageline SL with at least one insulating layer disposed therebetween,thereby forming a storage capacitor. The storage capacitor can keep thedata signal charged to the pixel electrode 132 stable even after the TFTis turned OFF. As illustrated in FIG. 1 (and FIG. 3), the storage linesSL constituting the storage capacitor receive a storage voltage from thepower source 164 through a storage supply line 126 connected to commonstorage pads 150 that are connected to the leftmost output pads of therespective circuit films 170.

The common electrode together with the pixel electrode 132 establishesan electric field for orienting the liquid crystals, and may be formedon the color filter substrate 113.

FIG. 3 is a plan view illustrating pads connected to a circuit film andto first and second conductive spacers in the LCD device of FIG. 1.

FIGS. 4A and 4B are alternative cross-sectional views taken alongsection line I-I′ in FIG. 3 illustrating alternative embodiments of anupper pad electrode 146 connecting the first and second conductivespacers.

As shown in FIGS. 3, 4A and 4B, a common electrode 158 receives a commonvoltage from the power source 164, via a common voltage input pad 160connected to the rightmost output pad of each of the circuit films 170,a first common voltage supply line 148, a first common voltage pad 220,and a first conductive spacer 120. The first common voltage pad 220 isformed between data fanout lines 172 connected to each of the severaldata driving chips 104 (FIG. 1). The first conductive spacer 120 isformed on the first common voltage pad 220.

The common electrode 158 also receives the common voltage from the powersource 164, via a second common voltage supply line 124 connected to thefirst common voltage pad 220, a second common voltage pad 210, and asecond conductive spacer 122. The second common voltage supply line 124is formed to cross (under or over) the plurality of data fanout lines172 connected to the plurality of data lines DL, and so, the secondcommon voltage supply line 124 is formed on a different plane (layer)from the data fanout lines 172. For a first example, the second commonvoltage supply line 124 may be formed of the same metal layer as anupper pad electrode 146 on a passivation layer 218 (as shown in FIG.4A); or for a second example, the second common voltage supply line 124may be formed of the same metal layer as a lower pad electrode 142 on alower substrate 101 (as shown in FIG. 4B). The second common voltagesupply line 124 is formed to cross (over or under) the adjacent datafanout lines 172 so that the first and second conductive spacers 120 and122 are electrically connected to each other, thereby preventing thecommon voltage from being delayed or rippled.

The second common voltage pad 210 is formed between the data fanoutlines 172 connected to the same data driving chip 104 (FIG. 1). Thesecond common voltage pad 210 is formed to be adjacent to the datafanout line 172 positioned at the center among the data fanout lines 172connected to the same data driving chip 104. The second conductivespacer 122 is formed on the second common voltage pad 210. Each of thefirst and second common voltage pads 220 and 210 includes a lower padelectrode 142 (formed of the same metal as the gate line GL on the sameplane), a pad contact hole 144 (penetrating a gate insulating layer 212and the passivation layer 218 that are formed to cover the lower padelectrode 142), and an upper pad electrode 146 (electrically connectedto the lower pad electrode 142 through the pad contact hole 144.

The LCD device of the present invention having a structure in which thenumber of data lines DL is decreased can compensate for a distortion ofthe common voltage by the second common voltage pad 210 and the secondconductive spacer 122 formed between the fanout lines 172.

FIG. 5 is a schematic view of an LCD device according to a secondexemplary embodiment of the present invention.

The LCD device of FIG. 5 has the same elements as the LCD device of FIG.1, except that second common voltage supply line is divided according toeach data driving chip. Therefore, a redundant detailed description ofthe same elements will be omitted.

The second common voltage supply line 124 is formed perpendicular to theplurality of data fanout lines 172 connected to the plurality of datalines DL. Here, the second common voltage supply line 124 is segmentedaccording to the data fanout lines 172 connected to each data drivingchip 104. For example, the first to third common voltage supply lines124A, 124B and 124C are separated from each other and respectively cross(over or under) the data fanout lines 172 connected to first to thirddata driving chips 104A, 104B and 104C. The total capacitance ofparasitic capacitors connected in parallel between the data fanout line172 connected to any one of the first to third data driving chips 104A,104B and 104C and the second common voltage supply line 124 is less thanthat of parasitic capacitors connected in parallel between all the datafanout lines 172 shown in FIG. 2 and the single second common voltageline 124. Therefore, an RC (resistor-capacitor) delay difference of thedata fanout line 172 is eliminated and thus a distortion of the datasignal can be reduced.

Moreover, since the second common voltage supply lines 124 (124A, 124 B,etc.) are separated according to the data driving chips 104, the commonvoltage can be differently supplied according to each of the datadriving chips 104. Therefore, if the degree of distortion in the commonelectrode 158 differs according to the location of the segment of secondcommon voltage supply line 124, the common voltage may be differentlysupplied according to the degree of distortion.

The LCD device of the present invention having a structure in which thenumber of data lines DL is decreased can compensate for a distortion ofthe common voltage by the second common voltage pad 210 and the secondconductive spacer 122 formed between the fanout lines 172. Furthermore,since the second common voltage supply line 124 is segmented, eachsegment of the second common voltage supply line 124 being associatedwith one of the data driving chips, the common voltage can bedifferently supplied.

FIG. 6 is a schematic view of an LCD device according to a thirdexemplary embodiment of the present invention.

The LCD device of FIG. 6 has the same elements as the LCD device of FIG.5, except that the storage supply line is divided (segmented) eachsegment corresponding to one of the data driving chips. Therefore, adetailed description of the same elements will be omitted.

The storage supply line 126 is formed to cross (over or under) theplurality of data lines DL and to be divided (segmented) with eachsegment of the storage supply line 126 corresponding to one of the datadriving chips 104. For example, first, second, and third storage supplylines 126A, 126B and 126C respectively correspond to the first, secondand third data driving chips 104A, 104B and 104C, and are separated fromeach other. The respective first, second and third storage supply lines126A, 126B and 126C independently supply a storage voltage to thestorage lines SL connected thereto. If there is a deviation in a storagevoltage corresponding to a location of the image display unit 108, thefirst, second and third storage supply lines 126A, 126B and 126C maydifferently supply the storage voltage to the corresponding storagelines SL.

The LCD device of the present invention having a structure in which thenumber of data lines DL is decreased can compensate for a distortion ofthe common voltage by the second common voltage pad and the secondconductive spacer formed between the fanout lines 172. Furthermore,since the second common voltage supply line is segmented, according tothe data driving chips, the common voltage can be differently supplied.In addition, since the storage supply line is segmented according to thedata driving chips, the storage voltage can be differently supplied.

FIG. 7 is a schematic view of an LCD device according to a fourthexemplary embodiment of the present invention. FIG. 8 is an enlargedplan view of a portion ‘A’ of the LCD device of FIG. 7.

The LCD device shown in FIG. 7 minimizes the variation (distortion) of avoltage of a data signal by supplying a signal having a phase oppositeto the common voltage to the storage line according to the degree ofdistortion of the common voltage by feedback of the common voltage. theLCD device of FIG. 7 has the same elements as the LCD device of FIG. 1,except for: a common voltage pad for supplying a common voltage to acommon electrode; a feedback dot and line adjacent to the common voltagepad; and a storage supply line for supplying an opposite phase signal tothe storage line according to the degree of distortion of the commonvoltage. Therefore, a detailed description of the same elements will beomitted.

The common voltage supply line 148, as shown in FIG. 8, connects thecommon voltage pad 220 to the common voltage input pad 160 connected tothe circuit film 170 (FIG. 7) with the shortest distance. The commonvoltage supply line 148 is formed to have relatively wide width and thusreduces its line resistance. The deviation of the common voltagesupplied to the common electrode 158 (see FIG. 4A or FIG. 4B) can beminimized by reducing the resistance of the common voltage supply line148.

A feedback dot 192 is connected to the circuit film 170 through afeedback pad 166 adjacent to the gate pad 162 via a feedback line 190(see FIG. 7). The feedback dot 192 is formed to be adjacent to the firstconductive spacer(s) 120 and feeds back the common voltage supplied tothe common electrode 158 through the first conductive spacer(s) 120. Thefirst conductive spacer(s) 120 and the feedback dot 192 are formed to beadjacent on one side of the same circuit film 170.

The storage supply line 126 overlaps a sealing member 188 (consisting ofa glass fiber, etc.) and thus the width of the storage line 126 isrelatively wide. For example, the width of the storage supply line 126is 4 mm to 6 mm. The resistance of the storage supply line 126 isreduced and a deviation of the storage voltage supplied to the storageline SL can be minimized. In this case, a storage connection line 202 isformed in a straight line shape to electrically connect the storagesupply line 126 and a storage supply pad 150 to each other with theshortest distance.

FIG. 9 is a cross-sectional view illustrating the LCD device of FIG. 7taken along section line II-II′ in FIG. 8.

As shown in FIG. 9 (see also FIG. 4A or 4B), the storage supply line 126is formed of the same metal as the gate line GL on the lower substrate101, and the data fanout line 172 is formed of the same metal as thedata line DL on the gate insulating layer 212 to cross (over) thestorage supply line 126. The storage line SL is formed of the same metalas the data line DL on the gate insulating layer 212. The storage lineSL and the storage supply line 126 are exposed through a connectioncontact hole 156 penetrating the passivation layer 218 and the gateinsulating layer 212. The exposed storage line SL and the storage supplyline 126 are connected to each other through a connection electrode 196.

The passivation layer 218 formed on the data fanout line 172 is formedof a thick organic layer capable of buffering pressure applied onto thesealing member 188 with a thickness of 2 μm or more. If pressure isapplied onto the LCD panel (pixel array) 130, the pressure istransmitted (e.g., by the LCD liquid) to the sealing member 188 and as aresult a shorting phenomenon may occur between the storage supply line126 and the data fanout line 172 under the sealing member 188. Thesealing member 188 is formed of a material containing an elastic softspacer in order to prevent the short phenomenon between the data fanoutline 172 and the storage supply line 126 due to a shock from theexterior.

Thus, the LCD device according to the present invention forms storagesupply line(s) having a relatively wide width by overlapping the sealingmember. Therefore, the deviation of the storage voltage can be minimizedby reducing the line resistance of the storage supply line.

As described above, the LCD device of the present invention having astructure in which the number of data lines is decreased can compensatefor a distortion of the common voltage by the second common voltage padand the second conductive spacer formed between the fanout lines. Inaddition, the LCD device of the present invention having a structure inwhich the number of data lines is decreased can minimize the deviationof the storage voltage by providing storage supply line(s) that overlapthe sealing member and have a relatively wide width.

While the invention has been shown and described with reference tocertain preferred embodiments thereof, it will be understood by thoseskilled in the art that various changes in form and details may be madetherein without departing from the spirit and scope of the invention asdefined by the appended claims.

1. A display device, comprising: a first substrate; a common electrodeformed on the first substrate; a second substrate bonded to the firstsubstrate; a gate line formed on the second substrate; a data lineformed on the second substrate, the data line intersecting with the gateline; a thin film transistor connected to the gate line and to the dataline; a pixel electrode connected to the thin film transistor and formedin a sub-pixel region having a long side extended in a first directionparallel to the gate line and having a short side extended in a seconddirection different from the first direction; a plurality of storagelines formed along the short side via the sub-pixel region; and astorage supply line interconnecting the plurality of storage lines. 2.The display device of claim 1, further comprising: a conductive spacerformed on the second substrate, the conductive spacer supplying a commonvoltage to the common electrode; and a feedback dot adjacent to theconductive spacer, the feedback dot feeding back the common voltage. 3.The display device of claim 2, wherein a compensation signal having aphase opposite to the common voltage fed back through the feedback dotis supplied to the storage line.
 4. The display device of claim 2,wherein the conductive spacer and the feedback dot are formed to beadjacent on one side of a circuit film on which a data driving chip ismounted.
 5. The display device of claim 2, wherein the conductive spacerand the feedback dot are formed to be adjacent on one side of a datadriving chip mounted on the second substrate.
 6. A liquid crystaldisplay device, comprising: a first substrate; a common electrode formedon the first substrate; a second substrate bonded to the first substrateby sealing member with liquid crystals disposed therebetween; a gateline formed on the second substrate; a data line formed on the secondsubstrate, the data line intersecting with the gate line; a thin filmtransistor connected to the gate line and to the data line; a pixelelectrode connected to the thin film transistor and formed in asub-pixel region having a long side extended in a first directionparallel to the gate line and having a short side extended in a seconddirection different from the first direction; a plurality of storagelines formed along the short side via the sub-pixel region; a storagesupply line interconnecting the plurality of storage lines. a conductivespacer formed on the second substrate, for supplying a common voltage tothe common electrode formed on a second substrate; and a feedback dotadjacent to the conductive spacer for feeding back the common voltage,wherein the conductive spacer and the feedback dot are formed to beadjacent on one side of a circuit film on which a data driving chip ismounted, wherein a compensation signal having a phase opposite to thecommon voltage fed back through the feedback dot is supplied to thestorage line.
 7. A liquid crystal display device, comprising: a firstsubstrate; a common electrode formed on the first substrate; a secondsubstrate bonded to the first substrate by sealing member with liquidcrystals disposed therebetween; a gate line formed on the secondsubstrate; a data line formed on the second substrate, the data lineintersecting with the gate line; a thin film transistor connected to thegate line and to the data line; a pixel electrode connected to the thinfilm transistor and formed in a sub-pixel region having a long sideextended in a first direction parallel to the gate line and having ashort side extended in a second direction different from the firstdirection; a plurality of storage lines formed along the short side viathe sub-pixel region; a storage supply line interconnecting theplurality of storage lines. a conductive spacer formed on the secondsubstrate, for supplying a common voltage to the common electrode formedon a second substrate; and a feedback dot adjacent to the conductivespacer for feeding back the common voltage, wherein the conductivespacer and the feedback dot are formed to be adjacent on one side of adata driving chip mounted on the second substrate, wherein acompensation signal having a phase opposite to the common voltage fedback through the feedback dot is supplied to the storage line.